JP3461831B2 - Method and apparatus for controlling transceiver operation in a wireless communication system - Google Patents

Description

FIELD OF THE INVENTION This invention relates to communication systems, and more particularly to wireless communication systems.

Background of the Invention Wireless communication systems have become popular for wireless mobile communications. One example of a wireless communication system is a cellular telephone system. For the design and operation of analog cellular telephone systems, see Blecher's "Latest Mobile Telephone Service", IEEE Bulletin on Vehicle Technology, Vol.VT.
29, No. 2, May 1980, pp. 238-244. The analog mobile cellular system is also called "AMPS".

EPO Patent No. 538,933, Sharpe et al., "Communication Receiver Using Prepaid ID Card," describes a communication receiver, such as a wireless pager, that inserts a card to load data about the operation of the receiver. There is. This data includes radio identification codes and prepaid credit units, which the receiver cancels as they are used. In addition, the data may include frequency and data rate information,
The receiver uses this to coordinate the reception of messages sent by the paging system.

UK Patent No. 2,225,512, Gillig et al. "Cellular Cordless Telephone" uses a cordless base station
It describes a cellular cordless telephone that also operates with a cellular base station and a cellular control terminal. When a cellular cordless telephone is in the area of a cordless base station, telephone calls are made on the cordless radio channel or transferred from the cellular radio channel to the cordless radio channel. When the cellular cordless telephone subsequently moves out of the area of this cordless base station, the telephone call is made on the cellular radio channel or transferred from the cordless radio channel to one of the cellular telephone channels.

Recently, a digital cellular telephone system using a time division multiple access (TDMA) structure has been proposed and realized.
The Electronic Industries Association (EIA) and the Telecommunications Industry Association (TIA) have established various standards for American Digital Cellular (ADC) configurations. The ADC configuration is a dual mode analog and digital system according to EIA / TIA document IS-54B. Telephones using the IS-54B dual mode configuration are currently marketed by the assignee of this invention.

In Europe, another standard has been established for digital cellular telephone systems. The European digital cellular system, also called GSM, also uses the TDMA architecture.
GSM also uses a subscriber identification module (SIM) that is removably attached to the cellular phone to identify the subscriber. SIM
Uses a "smart card" (also called a "chip card"). The card stores information such as subscription number, telephone number, confirmation code, etc. in a built-in chip. The SIM can be exchanged between telephone devices so that the user can attach the SIM to any compatible phone. For cellular phones using smart cards, see Dent US Pat. No. 5,091,942, Soggard Ras
U.S. Pat. No. 5,134,717, Leeds III (Reed
s, III) Other US Pat. No. 5,153,919. Citizen band (CB) radio is also known and uses a detachable crystal to set the oscillation frequency.

Proposals have recently been made to extend cellular telephone systems to wireless personal communication systems. A wireless personal communication system is one in which a mobile performs wireless voice, digital, video and / or multimedia communication and uses a wireless personal communication terminal. In this way, any form of information can be sent and received. A wireless personal communication terminal comprises a wireless telephone, such as a cellular telephone, and optionally other components for voice, digital, video and / or multimedia communications.

The wireless personal communication system comprises at least one base station. The base station is a low power transceiver,
It communicates with a wireless personal communication terminal such as a cellular phone at a limited distance of several tens of meters and is also electrically connected to a conventional wired network. Base stations allow wireless personal communication terminal owners to connect directly to a wired network without going through a wireless personal communication network, such as a cellular telephone network, which typically has high connection charges. When out of the service area of the base station, the personal communication terminal automatically communicates with the wireless personal communication network at a normal connection charge.

A major problem in implementing a wireless personal communication system is the overlapping frequencies between a wireless personal communication network (eg, a cellular telephone network) and a base station. As is known to those skilled in the art, the frequencies available for wireless communication are limited. In the United States, 30kHz wide 832 channels are allocated to cellular phones. Within this frequency range, network providers in each region can freely allocate and use these frequencies.

In the wireless personal communication system, the base station is supposed to transmit in the same frequency range as the wireless personal communication network. Therefore, if a base station operates on the same channel as a network covering the same area, co-channel interference may occur.

In order to avoid overlapping frequencies of the network and the base station, different frequency bands may be assigned to the network and the base station. However, such a hybrid system cannot efficiently allocate the frequency band. Furthermore, hybrid personal communication terminals can be expensive and complex due to the need for additional circuitry. Therefore, in order to provide an efficient wireless personal communication system, it is desirable that the base station operates in the same frequency band as the wireless personal communication network and does not cause co-channel interference.

UK patent application GB-A-2 260 468 discloses a wireless personal communication system, which uses terminals for wireless personal communication, a microcellular system (MC).
S) Depending on the location condition from the base station, it communicates with the MCS base station or the cellular mobile telephone system (CMTS). CMTS and MC
Since S uses a common frequency, it can automatically connect to either the CMTS or MCS. This patent is the basis for the preamble of the independent claims.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide an excellent wireless personal communication system and method.

Another object of the present invention is to provide a wireless personal communication system and method that reduces co-channel interference between a wireless personal communication network, such as a cellular telephone network, and a base station.

To these ends, the invention uses a frequency indicating means, preferably a smart card, which internally stores at least one indicator of the radio transmission frequency. The wireless personal communication terminal and / or the base station is detachably equipped with frequency indicating means and controls the wireless personal communication terminal and / or the base station to operate at a frequency corresponding to the frequency stored in the smart card. Since the smart card is issued by the wireless personal communication system operator, an appropriate frequency can be assigned to the base station to minimize co-channel interference with the wireless personal communication network. In addition, wireless personal communication system operators can use smart cards to rent out unused frequencies and obtain additional revenue from these frequencies.

The frequency indicating means (smart card) of the present invention is the second
At least one power level, which is also an indicator, is also stored, and it is desirable that the wireless personal communication terminal and / or base station operate at a frequency and power level corresponding to what is stored on the smart card. The base station preferably has a frequency and power level indicating means (smart card) removably attached to control the transmission frequency and power of the base station to accommodate the stored frequency and power levels. It is also desirable to provide the stored frequency and power level to a personal communication terminal that communicates with the base station, which also transmits at the frequency and power level corresponding to the base station.

Alternatively, frequency and power level indicating means (smart card) may be provided within the wireless personal communication terminal. In this case, the terminal, when connected to the base station, can set the frequency and power level of the base station and the terminal based on the power level and frequency stored in the smart card.

In one method of the present invention, a base station of a wireless telephone network electrically connects the base station to a wired telephone network to reduce co-channel interference with the wireless telephone network, a frequency indicating signal and preferably a power level indicating. The signal is received from a source external to the base station. In this case, the base station transceiver operates at a frequency and preferably a power level corresponding to the received frequency and power level indication signal. What is desirable is
At least one smart card storing at least one radio transmission frequency and power level indicator is removably attached to the base station for receiving the frequency and power level indicating signals, and at least one of the attached smart cards is
To obtain a signal representing one radio transmission frequency and power level. It is also desirable for the base station to transmit the frequency and power level to the wireless telephone with which it communicates based on the stored index so that the wireless telephone can also operate at the same frequency and power level as the base station.

Alternatively, a smart card is removably attached to the wireless phone. The smart card stores at least one indicator of radio transmission frequency and preferably power level. The radiotelephone transceiver is controlled to operate at a frequency and power level corresponding to the frequency and power level stored on this smart card. The radiotelephone also transmits a signal representative of the radio transmission frequency and preferably the power level to the base station, which operates at this power level.

By storing frequency and power level indicators using smart cards, network operators can assign frequencies to base stations so that co-channel interference with the wireless network is minimized. The system operator can also obtain additional revenue by lending unused frequencies in the cells of the network to base stations in the cells. In this way, an excellent wireless personal communication system and method can be provided.

BRIEF DESCRIPTION OF THE DRAWINGS FIGS. 1A and 1B are schematic diagrams of a wireless personal communication system including a base station and a wireless personal communication terminal,
Wireless communication between a terminal and a base station and wireless communication between a terminal and a wireless personal communication network are shown, respectively.

FIG. 2 is a schematic block diagram of the frequency and power level indicating means of the present invention.

  FIG. 3 is a schematic block diagram of the base station of the present invention.

FIG. 4 is a schematic block diagram of the base station radio frequency transceiver of the present invention.

FIG. 5 is a schematic block diagram of the wireless personal communication terminal of the present invention.

FIG. 6 is a flow chart showing the operation of the wireless personal communication system of the present invention.

Detailed Description of the Preferred Embodiments The present invention is described in detail below with reference to the accompanying drawings, which show preferred embodiments of the present invention. However, the invention can be implemented in many different forms and is not limited to the embodiments described herein.
These embodiments are intended to fully complete this disclosure and to fully demonstrate the scope of the invention to those skilled in the art.

1A and 1B are conceptual diagrams of a wireless personal communication system. As shown in FIG. 1A, the wireless personal communication system 100 includes at least one wireless personal communication network 1
02 (eg cellular telephone cell) with 10 cell antennas
6, sends and receives messages within the network shown at 104. The network 102 also connects to a wired network 108. As is well known to those skilled in the art, wireless personal communication system 100 typically includes many wireless personal communication networks or cells 102 to cover a large area.

Further in FIG. 1A, system 100 comprises base station 110. The base station 110 comprises a low power transceiver and the base station antenna 112 transmits and receives within a limited base station range 114, typically on the order of tens of meters. Thus, the base station can be used for transmitting and receiving wireless personal communications at home or office. Base station 110
Is also electrically connected to the wired network 108.

Further, the wireless personal communication terminal 12 shown in FIG. 1A.
0 performs wireless communication between the base station 110 and the network 102 via the antenna 122. The wireless personal communication terminal comprises a wireless telephone such as a cellular telephone. The wireless personal communication terminal 120 may also include, for example, a computer keyboard and display, a scanner, graphics and multimedia equipment.

As shown in FIG. 1A, when the terminal 120 is within range 114 of the base station 110, the wireless link 124 between them is automatically set up. As shown in FIG. 1B, when the terminal 120 is outside the range 114 of the base station 110 but within the range 104 of the network 102, a new wireless link 126 is automatically established with the network 102. Therefore, when the user is relatively close to the base station 110 (that is, in the home or office), the user wirelessly communicates with the base station 110, and a high-price wireless personal communication network
Bypass 102. When the user is relatively far from the base station 110, it communicates with the network 102.

As is well known to those skilled in the art, a complete wireless personal communication system 100 generally comprises a number of base stations 110, terminals 120 and wireless networks (cells) 102. Also, as those skilled in the art will appreciate, conventional communication and handoff protocols may be used with the present invention, but will not be described in detail here. For convenience of explanation, the frequency band allocation is the IS-54B cellular telephone frequency band allocation, which is shown in Table 1 below.

In the wireless personal communication system 100 shown in FIGS. 1A and 1B, it is important to avoid co-channel interference between the base station 110 and the network 102. In the present invention, the operator of network 102 has been pre-assigned by the supervisory authority to use the frequency range within the area, so that the frequency and preferably the power level of base station 110 can be assigned. A network operator may assign frequencies and preferably power levels to base stations 110 to minimize co-channel interference and maximize revenue from the assigned frequency range. The frequency indicating means is in the form of a smart card, a removable memory module or other token, and is removably attached to the base station 110 or the personal communication terminal 120 to provide frequency information and preferably power level information, Controls communication between terminals and base stations.

FIG. 2 shows the frequency and power level indicating means of the present invention. As shown, the frequency and power level indicating means 200 is preferably a smart card 202 (also called a "chip card") or other token, comprising a memory 208, in which at least one radio transmission frequency 204. And at least one power level 206 index. Memory 208 is preferably an electrically erasable PROM
(EEPROM) and operates under the control of the controller 210. FIG. 2 shows a plurality of smart card electrical contacts 212a-
Only three of the 212n are shown, but these show the frequency index 204 and the power level index 206 outside the smart card 202.
You can communicate with. As will be appreciated by those skilled in the art, the memory 208 may include other information 214, such as identification information such as a subscription number or telephone number or verification code, and / or other pre-programmed telephone numbers. Smart cards are currently the European Digital Cellular System (GSM)
Used to identify subscribers. The GSM smart card is called the subscriber identification module (SIM) and is an international standard ISO.
7816-1, -2, -3.

FIG. 3 shows a block diagram of a preferred embodiment of the present invention in which the base station 110 comprises means for removably attaching frequency and power level indicating means 200. FIG. 3 shows a recess 302 for removably attaching the frequency and power level indicating means 200 to the base station 110. However, it may be removably attached using other methods. Contact 212a-
212n makes electrical contact with corresponding contacts 304a-304n on the base station and obtains signals representative of frequency index 204 and power level index 206 from smart card 202. Electromagnetic, optical, or other means may be used to obtain the signal from the removably attached smart card 202.

In the present invention, base station 110 controls the operation of base station 110 using the obtained frequency 204 and power level 206. It is also desirable to control the operation of wireless personal communication terminal 120 using frequency signals and power level signals. This will be described later. Also, as described below, terminal 120 may be controlled to operate at the same frequency and power level as base station 110, or different frequencies and power levels may be used. If different frequencies or power levels are used, the smart card 202 may store multiple frequencies 204 and power levels 206, and the base station 110 or terminal 120 may use the smart card 20.
The second frequency and power level may be determined from one index stored in 2. The base station 110 preferably does not operate without the frequency and power level indicating means 200 attached. By doing this,
The network operator can profit from the use of frequencies while at the same time preventing wireless communication between the base station 110 and the terminal 120 from interfering with the cellular network.

Further with respect to FIG. 3, other circuitry of base station 110 will be described. The design of the other circuitry of base station 110 is well known to those skilled in the art and need not be described in detail. The microprocessor 360 is, for example, a Zylog Z80 microcontroller and controls the base station 110. The wireless transceiver 310 is connected to the terminal 12 by the antenna 112.
0 and two-way communication with the network 102. The signal received by the antenna 112 is converted by the wireless transceiver 310 and given to the demodulator 315. The demodulator produces a bitstream, ie a series of binary data representing the received data. This bit stream is then received by a digital signal processor (DS
P) 355 for conversion to analog audio signals by methods well known to those skilled in the art. The obtained analog signal is sent to the subscriber loop interface circuit 345. Loop interface circuit 345 is a commonly used circuit that interfaces with wired network 108, also referred to as the public switched telephone network (PSTN). The PSTN108 is, for example, an ordinary "wired" telephone system supplied by a local telephone company.
Use copper wire, fiber optics or other static transmission channels.

Further in FIG. 3, the microprocessor 360 controls the receiving DSP 355. Microprocessor 360 provides timing signals and instructions. Operating instructions for the receiving DSP 355 are typically stored in an electrically erasable PROM (EEPROM) 330. Flash ROM 335 typically stores the instructions of microprocessor 360 itself. These instructions are uploaded to the microprocessor 360 at initialization. SRAM 325 is a static RAM and is typically used by DSP 355 and microprocessor 360 as a scratchpad memory for temporary storage of information. A power management and distribution circuit 340 also connects to the microprocessor 360.

When transmitting, the signal received from the wired network 108 is sent to the transmitting DSP 320 by the loop interface circuit 345. The transmitting DSP 320 digitizes the analog signal, converts it into a bit stream, and sends it to the modulator 305. The transmitting circuit basically performs the complementary function of the above receiving circuit.

FIG. 4 shows a schematic block diagram of the wireless transceiver 310 of FIG. As shown, transceiver 310 includes circuitry for receiving and transmitting radio frequency signals. The signal received by the antenna 112 is sent to the receiving circuit by the duplexer 401. A duplexer is a filter with two different band responses, one passing the signal in the receive band and the other the signal in the transmit band. In the ADS configuration described above, the receive and transmit frequencies are separated by 45mHz. The duplexer 401 allows signals to be transmitted and received simultaneously.

After passing through the duplexer 401, the received signal is amplified by a low noise radio frequency (RF) amplifier 402. This amplifier provides enough benefit to recover the losses that may occur in the pre-circuit. After amplification, unnecessary elements of the signal are filtered by the reception filter 403. After filtering, this signal and the second signal generated by the channel synthesizer 415 and filtered by the local oscillator (LO) filter 414 are mixed by the mixer 404,
Set to the first intermediate frequency (IF). Next, the first IF signal is fed to the amplifier 4
Amplify at 05 and remove unwanted mixed products with IF filter 406. After filtering, the signal from local oscillator synthesizer 416 is used to mix in the first IF and mixer 407 to another low frequency or second IF signal. Next, the second IF signal is filtered by two filters 408 and 410, amplified by multistage amplifiers 409 and 411, and then IF signal 412 and radio signal strength indication (RSSI) signal 413 are obtained.
To get Then, for example, Dent's U.S. Pat.
Perform the detection process described in No. 9. This patent is cited as a reference.

When transmitting, the transmitting DSP 320 (FIG. 3) produces a data stream 419. In the ADC configuration, the data stream is burst-configured to perform time division multiplexing transmission with other users. The reference oscillator 418 produces an accurate frequency, which the RF circuit uses as a stable reference. The output of oscillator 418 is sent to multiplier 421 to increase the frequency by a factor of six. This frequency is then fed into a quadrature network 422, which produces two signals of equal amplitude and in quadrature (ie 90 ° offset). These quadrature signals and data stream 419 are combined in modulator 423 to produce a modulated signal. For this, see DE Norton (Norto
n) Other "I and Q Modulators for Cellular Communication Systems", Microwave Journal, Vol. 34, No. 10, 1
October 991, pp. 63-79. The modulated signal is sent to the mixer 424, where it is converted to radio frequency. Exact Radio Frequency Channel Synthesizer 41
Determined by the local oscillator signal provided by 5. This radio frequency signal is sent to the variable gain control amplifier 425. The gain of this amplifier is controlled by the voltage on the transmit power control line 420, which determines the final output power. This is because the gain of the linear power amplifier 427 is fixed. The filtering is performed by the transmission filter 426.

In the present invention, the frequency index 204 stored on the smart card 202 is converted into synthesizer instructions and provided on line 417 to generate the required transmit and receive frequencies. Further, the power level index 206 stored in the smart card 202 is converted into a transmission power control signal and is given to the line 420 to control the transmission power. This conversion is preferably performed by microprocessor 360 using conventional techniques. The operation of setting the frequency and power level will be described later with reference to FIG.

FIG. 5 shows another embodiment of the present invention in which the frequency and power level indicating means 200 is used in a wireless personal communication terminal 120 to control its frequency and power level and / or by wireless communication to a base station 110. Control the frequency and power level of the. The design of the terminal 120 is the same as the design of the base station 110 (FIG. 3), but there is no loop interface circuit 345. Terminal 120
Is a cellular phone, keypad 502, display 5
04, speaker 506, microphone 508. To make a wireless personal communication terminal for receiving and transmitting audio, video, data and / or multimedia signals, the keypad 502 can be a complete personal computer keyboard and the display 504 can be a large graphics display. It may also include a scanner 510 and other devices 512 such as disk drives and modems. Other than using the smart card 200 to set the power level and frequency, the design of the terminal 120 is well known to those skilled in the art and will not be described in detail here.

Referring now to FIG. 6, the operation of controlling the frequency and power level of a personal communication terminal and / or base station based on the frequency and power level information stored in the smart card in accordance with the present invention. Other operations may also be used.

Operation begins with powering terminal 120 at block 602. Upon application of power, terminal 120 scans the set of control channels assigned to base station 110 and determines at block 606 whether a signal level above a threshold is detected. Each base station 110 has
Generally, only one set of control channels is assigned. If a signal level above the threshold is detected, terminal 120 is within range 114 of base station 110. If no signal level above the threshold is detected, then terminal 120 is not within range of base station 110 and block 608 initiates communication with network 102 in a conventional manner.

Returning to block 606, if a base station control channel signal above a threshold is detected, then at block 610 terminal 120 tracks the strongest signal. Once tracking begins, at block 612 the terminal 120 registers. Similar to the cellular telephone system, this registration information has a predetermined power level and a predetermined frequency depending on the tracked control channel.

During registration, the base station 110 commands the terminal 120 to tune to another frequency, to which the base station opens a channel and transmits at a certain power level. This may be a frequency and power level determined by the frequency and power level index, or a different frequency and power level. When the transmission is complete, the base station drops the control channel frequency to prevent another user from using the same base station.

In the present invention, the stored frequency and power level indicators are obtained from smart card 202. This card is
Although it is desirable to be detachably attached to the base station 110, it may be detachably attached to the terminal 120. Block 616
Convert the obtained frequency and power level into a signal with
This signal is used to set up synthesizer 415 and amplifier 425 of the device with the smart card removably attached. Next, at block 618, signals representative of frequency and power level (same frequency / power level or different frequency / power levels) are transmitted to other devices that do not have smart cards. At block 620, the device uses the received frequency and power level signals to configure its synthesizer and amplifier. Next, at block 622, communication between the base station 110 and the terminal 120 occurs at the frequency and power level set in the previous operation.

As will be appreciated by those skilled in the art, smart card 202 may store separate voice channel frequencies and power levels for base station 110 and terminal 120. The power level may be different for the base station and the terminal, for example when the base station antenna is larger or the base station receiver is more sensitive. The frequency may be different. This is because, in the duplex communication transceiver, the terminal and the base station generally do not transmit or receive on the same frequency. Alternatively, one frequency and power level may be stored and a second frequency and power level may be stored at this one.
It may be determined from two frequencies and power levels.

Therefore, the network provider can use frequency and power level indicating means such as smart cards to assign the frequency and power level of communication between the base station and the terminal. By allocating frequencies and power levels for communication between the base station and the terminals, co-frequency interference in the cells of the network is reduced and the network provider gets additional revenue from the frequency range allocated to the base station.

The drawings and the description disclose the general preferred embodiments of the invention. Although specific terms have been used, they are generally used in terms of description and not limitation. The scope of the invention is defined in the following claims.

Front page continued (58) Fields surveyed (Int.Cl. ⁷ , DB name) H04B ^7/ 24-7/26 H04Q ⁷ /00-7/38

Claims (11)

(57) [Claims] 1. A plurality of cells (104) are provided, each cell being one.
Cellular network (102) communicating on a set of allocated frequencies
A wireless personal communication terminal (120) comprising a first wireless transceiver means, and a base station comprising a second wireless transceiver means electrically connected to the wired telephone network (108) and in communication with said first wireless transceiver means ( 110) in a wireless personal communication system (100), wherein the base station is in a first cell of the plurality of cells having a first set of allocated frequencies, and the first transceiver means is , The wireless personal communication terminal is in the first cell of the plurality of cells and is relatively far from the base station, the first of the assigned frequencies.
Communicating with the first cell of the plurality of cells using a set, and when the wireless personal communication terminal is relatively close to the base station, the frequencies of the frequencies assigned to the plurality of cells in the cellular network are In the wireless personal communication system for communicating with the first wireless transceiver means using at least one wireless transmission frequency selected from the set but different from the first set of allocated frequencies, Frequency setting means (200) which is detachably attached to at least one of the base station and the wireless personal communication terminal in the first cell, and stores the setting of the at least one wireless transmission frequency; and the detachable type. Means for obtaining a signal representative of the at least one radio transmission frequency from the attached frequency setting means; and the first transceiver hand. By controlling the radio personal communication system which comprises means for communicating with the base station using at least one radio transmission frequency, the. 2. The wireless communication system according to claim 1, wherein the frequency setting means (200) is a smart card (202). 3. The wireless personal communication terminal (12
The wireless communication system according to claim 1, wherein 0) comprises a wireless telephone. 4. The wireless personal communication system of claim 3, wherein the wireless telephone is a cellular telephone. 5. The wireless personal communication terminal (12
The wireless personal communication system according to claim 1, wherein 0) comprises a cellular telephone, and said wireless personal communication network (102) is a cellular telephone network. 6. A plurality of cells (104), each cell being one
A base station (110) operating in a cellular network communicating at a set of allocated frequencies, the base station comprising means for electrically connecting the base station to a wired telephone network (108),
The base station is in a first cell having a first set of allocated frequencies in the plurality of cells, and the base station is selected from the set of frequencies allocated to the plurality of cells in the cellular network. The first of the allocated frequencies
Further comprising wireless transceiver means operating using a different frequency from the set, in the base station, means for receiving an externally generated frequency setting signal to the base station, and in accordance with the external frequency setting signal, the Means for operating the transceiver means at a frequency corresponding to the received frequency setting signal, and a base station. 7. The frequency setting signal receiving means includes a means for detachably attaching a frequency setting means (200) storing at least one radio transmission frequency setting, and the at least one of the attached frequency setting means. 1
Means for obtaining a signal representative of one radio transmission frequency, said at least one radio transmission frequency being selected from said set of frequencies assigned to a plurality of cells in said cellular network The base station (110) according to claim 6, comprising: a means different from one set. 8. The base station (110) according to claim 6, wherein the frequency setting signal receiving means includes means for receiving a radio signal corresponding to the frequency setting signal from a radio telephone. 9. The base station (110) of claim 7, wherein the detachably attachable means comprises detachably attachable a smart card (202) storing the setting of at least one wireless transmission frequency. ). 10. The frequency setting signal receiving means comprises means for receiving an externally generated frequency setting signal and power level setting signal to the base station, and the operating means applies to the received frequency and power level setting signal. Means for operating the transceiver means at a corresponding frequency and power level, the received frequency being selected from the set of assigned frequencies, and the first set of assigned frequencies being Different,
7. The base station (11) according to claim 6, wherein frequency interference between the transceiver means and the cellular network is reduced.
0). 11. A cellular network (10) comprising a plurality of cells (104), each cell communicating at a set of assigned frequencies.
2), a wireless personal communication terminal (120) having a first wireless transceiver means, and a base having a second wireless transceiver means electrically connected to the wired telephone network (108) and in communication with the first wireless transceiver means. Bureau (110)
A method of operating a wireless personal communication system (100) comprising: a base station in a first cell having a first set of allocated frequencies in the plurality of cells; Means, when the wireless personal communication terminal is in a first cell of the plurality of cells and is relatively far from the base station, using the first set of assigned frequencies for the plurality of cells of the plurality of cells. When communicating with a first cell and the wireless personal communication terminal is relatively close to the base station, an assigned frequency selected from the set of frequencies assigned to a plurality of cells in the cellular network is assigned. In the method of communicating with the first wireless transceiver means using at least one wireless transmission frequency different from the first set of Providing at least one base station in the first cell of the plurality of cells and detachably attached to the wireless personal communication terminal to store the at least one wireless transmission frequency setting; Obtaining a signal representative of said at least one radio transmission frequency from a frequency setting means mounted in a formula, controlling said first transceiver means to communicate with said base station using said at least one radio transmission frequency And, including.